Monitoring Effector Translocation with the TEM-1 Beta-Lactamase Reporter System: From Endpoint to Time Course Analysis

Among the bacterial secretion systems, the Type III, IV, and VI secretion systems enable bacteria to secrete proteins directly into a target cell. This specific form of secretion, referred to as "translocation", is essential for a number of pathogens to alter and/or kill the targeted cell. The translocated proteins, called effector proteins, can directly interfere with the normal processes of the targeted cell, preventing elimination of the pathogen and promoting its multiplication. The function of the effector proteins varies greatly depending on the considered pathogen and the targeted cell. In addition, there is often no magic bullet and the number of effector proteins can range from a handful to hundreds, with, for instance, over 300 effector proteins substrate of the Icm/Dot Type IV secretion system in the human pathogen Legionella pneumophila. Identifying, detecting, and monitoring the translocation of each of the effector proteins represent an active field or research and are key to understanding the bacterial molecular weaponry. Translational fusion of the effector with a reporter protein of known activity remains the best method to monitor effector translocation. The development of a fluorescent substrate for the TEM-1 beta-lactamase has turned this antibiotic-resistance protein into a highly versatile reporter system to investigate protein transfer events associated with microbial infection of host cells. We here described a simple protocol to assay translocation of an effector protein by the Icm/Dot system of the human pathogen Legionella pneumophila. Taking advantage that the protonophore CCCP inhibits the secretion activity, this simple protocol can be derived into a time course analysis to follow the kinetic of effector translocation into target cells.

Detection of Cells Translocated with Yersinia Yops in Infected Tissues Using β-Lactamase Fusions

Development of the TEM-CCF2/4-AM FRET-based system has enabled investigators to track translocation of effector proteins into mammalian cells during infection. This allows for separation of translocated and non-translocated cell populations for further study. Yersinia strains expressing translational Yop-TEM fusions, containing the secretion and translocation signals of a Yop with the TEM-1 portion of β-lactamase, are used to infect mice, tissues isolated from mice, or mammalian cells in culture. Infected and harvested mammalian cells are treated with either CCF2-AM or CCF4-AM, and cleavage of this fluorescent compound by TEM is detected by fluorescence-activated cell sorting (FACS) analysis. A shift from green to blue emission spectra of individual cells is indicative of translocation of a given Yop-TEM fusion protein into the host cell during Yersinia infection due to a disruption in FRET between the two fluors of the compound. In Yersinia, this method has been used to understand Type III secretion dynamics and Yop functions in cells translocated by effectors during infection. Here, we describe how to generate Yop-TEM constructs, and how to detect, quantify, isolate, and study Yop-TEM containing cells in murine tissues during infection and in ex vivo tissues by cell sorting and flow cytometry analysis. In addition, we provide guidance for analyzing TEM-positive cells via a plate reader and fluorescent microscopy.

Assessing Vacuolar Escape of Listeria Monocytogenes

Listeria monocytogenes is a bacterial pathogen which invades and multiplies within non-professional phagocytes. Signaling cascades involved in cellular entry have been extensively analyzed, but the events leading to vacuolar escape remain less clear. In this chapter, we detail a microscopy FRET-based assay which allows quantitatively measuring L. monocytogenes infection and escape from its internalization vacuole, as well as a correlative light/electron microscopy method to investigate the morphological features of the vacuolar compartments containing L. monocytogenes.

Monitoring Effector Translocation using the TEM-1 Beta-Lactamase Reporter System

Among the bacterial secretion systems, the Type III, IV, and VI secretion systems enable bacteria to secrete proteins directly into a target cell. This specific form of secretion, referred to as translocation, is essential for a number of pathogens to alter or kill targeted cells. The translocated proteins, called effector proteins, can directly interfere with the normal processes of the targeted cells, preventing elimination of pathogens and promoting their multiplication. The function of effector proteins varies greatly depending on the considered pathogen and the targeted cell. In addition, there is often no magic bullet, and the number of effector proteins can range from a handful to hundreds, with, for instance, a substrate of over 300 effector proteins of the Icm/Dot Type IV secretion system in the human pathogen Legionella pneumophila. Identifying, detecting, and monitoring the translocation of each of the effector proteins represents an active field of research and is key to understanding the bacterial molecular weaponry. Translational fusion of an effector with a reporter protein of known activity remains the best method to monitor effector translocation. The development of a fluorescent substrate for the TEM-1 beta-lactamase has turned this antibiotic-resistant protein into a highly versatile reporter system for investigating protein transfer events associated with microbial infection of host cells. Here we describe a simple protocol to assay the translocation of an effector protein by the Icm/Dot system of the human pathogen Legionella pneumophila.

Measurement of Export to the Cytosol in Dendritic Cells Using a Cytofluorimetry-Based Assay

The presentation of exogenous antigens on MHC class I molecules, known as cross-presentation, is a key function of dendritic cells (DCs). Cross-presentation via the cytosolic pathway involves antigen export from endocytic compartments to the cytosol. We have recently developed a cytofluorimetry-based assay to examine the kinetics and the efficiency of antigen export to the cytosol in DC populations. In this assay, DCs are loaded with a FRET-sensitive cytosolic substrate of β-lactamase, CCF4. Following uptake of β-lactamase by the DCs, the enzyme undergoes export to the cytosol leading to cleavage of the FRET dye. This cleavage and switch of fluorescence are analyzed by flow cytometry, allowing a quantitative measurement of this event.